﻿/********************************************************************************
 *                                                                              *
 * This file is part of IfcOpenShell.                                           *
 *                                                                              *
 * IfcOpenShell is free software: you can redistribute it and/or modify         *
 * it under the terms of the Lesser GNU General Public License as published by  *
 * the Free Software Foundation, either version 3.0 of the License, or          *
 * (at your option) any later version.                                          *
 *                                                                              *
 * IfcOpenShell is distributed in the hope that it will be useful,              *
 * but WITHOUT ANY WARRANTY; without even the implied warranty of               *
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the                 *
 * Lesser GNU General Public License for more details.                          *
 *                                                                              *
 * You should have received a copy of the Lesser GNU General Public License     *
 * along with this program. If not, see <http://www.gnu.org/licenses/>.         *
 *                                                                              *
 ********************************************************************************/

/********************************************************************************
 *                                                                              *
 * Implementations of the various conversion functions defined in IfcGeom.h     *
 *                                                                              *
 ********************************************************************************/

#include <set>
#include <cassert>
#include <algorithm>

#include <gp_Pnt.hxx>
#include <gp_Vec.hxx>
#include <gp_Dir.hxx>
#include <gp_Pnt2d.hxx>
#include <gp_Vec2d.hxx>
#include <gp_Dir2d.hxx>
#include <gp_Mat.hxx>
#include <gp_Mat2d.hxx>
#include <gp_GTrsf.hxx>
#include <gp_GTrsf2d.hxx>
#include <gp_Trsf.hxx>
#include <gp_Trsf2d.hxx>
#include <gp_Ax3.hxx>
#include <gp_Ax2d.hxx>
#include <gp_Pln.hxx>
#include <gp_Circ.hxx>

#include <TColgp_Array1OfPnt.hxx>
#include <TColgp_Array1OfPnt2d.hxx>
#include <TColStd_Array1OfReal.hxx>
#include <TColStd_Array1OfInteger.hxx>

#include <Geom_Line.hxx>
#include <Geom_Circle.hxx>
#include <Geom_Ellipse.hxx>
#include <Geom_TrimmedCurve.hxx>

#include <Geom_Plane.hxx>
#include <Geom_OffsetCurve.hxx>
#include <Geom_OffsetSurface.hxx>
#include <Geom_CylindricalSurface.hxx>
#include <Geom_SurfaceOfLinearExtrusion.hxx>

#include <GeomAPI_IntCS.hxx>
#include <GeomAPI_IntSS.hxx>

#include <BRepBndLib.hxx>
#include <BRepOffsetAPI_Sewing.hxx>
#include <BRepBuilderAPI_MakeFace.hxx>
#include <BRepBuilderAPI_MakeEdge.hxx>
#include <BRepBuilderAPI_MakeWire.hxx>
#include <BRepBuilderAPI_MakePolygon.hxx>
#include <BRepBuilderAPI_MakeVertex.hxx>

#include <TopoDS.hxx>
#include <TopoDS_Wire.hxx>
#include <TopoDS_Face.hxx>
#include <TopoDS_CompSolid.hxx>

#include <TopExp.hxx>
#include <TopExp_Explorer.hxx>

#include <BRepPrimAPI_MakePrism.hxx>
#include <BRepBuilderAPI_MakeShell.hxx>
#include <BRepBuilderAPI_MakeSolid.hxx>
#include <BRepPrimAPI_MakeHalfSpace.hxx>
#include <BRepAlgoAPI_Cut.hxx>
#include <BRepAlgoAPI_Fuse.hxx>
#include <BRepAlgoAPI_Common.hxx>

#include <BRepAlgo_NormalProjection.hxx>

#include <ShapeFix_Shape.hxx>
#include <ShapeFix_ShapeTolerance.hxx>
#include <ShapeFix_Solid.hxx>

#include <ShapeAnalysis_Curve.hxx>
#include <ShapeAnalysis_Surface.hxx>

#include <BRepFilletAPI_MakeFillet2d.hxx>

#include <TopLoc_Location.hxx>

#include <GProp_GProps.hxx>
#include <BRepGProp.hxx>

#include <BRepBuilderAPI_Transform.hxx>
#include <BRepBuilderAPI_GTransform.hxx>

#include <BRepCheck_Analyzer.hxx>

#include <BRepGProp_Face.hxx>

#include <BRepMesh_IncrementalMesh.hxx>
#include <BRepTools.hxx>
#include <BRepTools_WireExplorer.hxx>

#include <Poly_Triangulation.hxx>
#include <Poly_Array1OfTriangle.hxx>

#include <TopTools_IndexedMapOfShape.hxx>
#include <TopTools_IndexedDataMapOfShapeListOfShape.hxx>
#include <TopTools_ListIteratorOfListOfShape.hxx>

#include <BOPAlgo_PaveFiller.hxx>
#include <BOPAlgo_BOP.hxx>

#include <GCPnts_AbscissaPoint.hxx>

#include <Standard_Version.hxx>

#include "../ifcparse/IfcSIPrefix.h"
#include "../ifcparse/IfcFile.h"
#include "../ifcgeom/IfcGeom.h"

#if OCC_VERSION_HEX < 0x60900
#ifdef _MSC_VER
#pragma message("warning: You are linking against Open CASCADE version " OCC_VERSION_COMPLETE ". Version 6.9.0 introduces various improvements with relation to boolean operations. You are advised to upgrade.")
#else
#warning "You are linking against linking against an older version of Open CASCADE. Version 6.9.0 introduces various improvements with relation to boolean operations. You are advised to upgrade."
#endif
#endif

bool IfcGeom::Kernel::create_solid_from_compound(const TopoDS_Shape& compound, TopoDS_Shape& shape) {
	BRepOffsetAPI_Sewing builder;
	builder.SetTolerance(getValue(GV_POINT_EQUALITY_TOLERANCE));
	builder.SetMaxTolerance(getValue(GV_POINT_EQUALITY_TOLERANCE));
	builder.SetMinTolerance(getValue(GV_POINT_EQUALITY_TOLERANCE));
	TopExp_Explorer exp(compound,TopAbs_FACE);
	if ( ! exp.More() ) return false;
	for ( ; exp.More(); exp.Next() ) {
		TopoDS_Face face = TopoDS::Face(exp.Current());
		builder.Add(face);
	}
	builder.Perform();
	shape = builder.SewedShape();
	if (shape.ShapeType() == TopAbs_SHELL) {
		try {
			ShapeFix_Solid sf_solid;
			sf_solid.LimitTolerance(getValue(GV_POINT_EQUALITY_TOLERANCE));
			shape = sf_solid.SolidFromShell(TopoDS::Shell(shape));
		} catch(...) {}
	}
	return true;
}

bool IfcGeom::Kernel::is_compound(const TopoDS_Shape& shape) {
	bool has_solids = TopExp_Explorer(shape,TopAbs_SOLID).More() != 0;
	bool has_shells = TopExp_Explorer(shape,TopAbs_SHELL).More() != 0;
	bool has_compounds = TopExp_Explorer(shape,TopAbs_COMPOUND).More() != 0;
	bool has_faces = TopExp_Explorer(shape,TopAbs_FACE).More() != 0;
	return has_compounds && has_faces && !has_solids && !has_shells;
}

const TopoDS_Shape& IfcGeom::Kernel::ensure_fit_for_subtraction(const TopoDS_Shape& shape, TopoDS_Shape& solid) {
	const bool is_comp = is_compound(shape);
	if (!is_comp) {
		return solid = shape;
	}
	create_solid_from_compound(shape, solid);
	
	// If the SEW_SHELLS option had been set this precision had been applied
	// at the end of the generic convert_shape() call.
	const double precision = getValue(GV_PRECISION);
	apply_tolerance(solid, precision);
	
	return solid;
}

bool IfcGeom::Kernel::convert_openings(const IfcSchema::IfcProduct* entity, const IfcSchema::IfcRelVoidsElement::list::ptr& openings, 
							   const IfcGeom::IfcRepresentationShapeItems& entity_shapes, const gp_Trsf& entity_trsf, IfcGeom::IfcRepresentationShapeItems& cut_shapes) {

	// TODO: Refactor convert_openings() convert_openings_fast() and convert(IfcBooleanResult) to use
	// the same code base and conform to the same checks and logging messages.

	// Iterate over IfcOpeningElements
	IfcGeom::IfcRepresentationShapeItems opening_shapes;
	unsigned int last_size = 0;
	for ( IfcSchema::IfcRelVoidsElement::list::it it = openings->begin(); it != openings->end(); ++ it ) {
		IfcSchema::IfcRelVoidsElement* v = *it;
		IfcSchema::IfcFeatureElementSubtraction* fes = v->RelatedOpeningElement();
		if ( fes->is(IfcSchema::Type::IfcOpeningElement) ) {
			if (!fes->hasRepresentation()) continue;

			// Convert the IfcRepresentation of the IfcOpeningElement
			gp_Trsf opening_trsf;
			if (fes->hasObjectPlacement()) {
				try {
					convert(fes->ObjectPlacement(),opening_trsf);
				} catch (...) {}
			}

			// Move the opening into the coordinate system of the IfcProduct
			opening_trsf.PreMultiply(entity_trsf.Inverted());

			IfcSchema::IfcProductRepresentation* prodrep = fes->Representation();
			IfcSchema::IfcRepresentation::list::ptr reps = prodrep->Representations();
						
			for ( IfcSchema::IfcRepresentation::list::it it2 = reps->begin(); it2 != reps->end(); ++ it2 ) {
				convert_shapes(*it2,opening_shapes);
			}

			const unsigned int current_size = (const unsigned int) opening_shapes.size();
			for ( unsigned int i = last_size; i < current_size; ++ i ) {
				opening_shapes[i].prepend(opening_trsf);
			}
			last_size = current_size;
		}
	}

	// Iterate over the shapes of the IfcProduct
	for ( IfcGeom::IfcRepresentationShapeItems::const_iterator it3 = entity_shapes.begin(); it3 != entity_shapes.end(); ++ it3 ) {
		TopoDS_Shape entity_shape_solid;
		const TopoDS_Shape& entity_shape_unlocated = ensure_fit_for_subtraction(it3->Shape(),entity_shape_solid);
		const gp_GTrsf& entity_shape_gtrsf = it3->Placement();
		if ( entity_shape_gtrsf.Form() == gp_Other ) {
			Logger::Message(Logger::LOG_WARNING, "Applying non uniform transformation to:", entity->entity);
		}
		TopoDS_Shape entity_shape = apply_transformation(entity_shape_unlocated, entity_shape_gtrsf);

		// Iterate over the shapes of the IfcOpeningElements
		for ( IfcGeom::IfcRepresentationShapeItems::const_iterator it4 = opening_shapes.begin(); it4 != opening_shapes.end(); ++ it4 ) {
			TopoDS_Shape opening_shape_solid;
			const TopoDS_Shape& opening_shape_unlocated = ensure_fit_for_subtraction(it4->Shape(),opening_shape_solid);
			const gp_GTrsf& opening_shape_gtrsf = it4->Placement();
			if ( opening_shape_gtrsf.Form() == gp_Other ) {
				Logger::Message(Logger::LOG_WARNING,"Applying non uniform transformation to opening of:",entity->entity);
			}
			TopoDS_Shape opening_shape = apply_transformation(opening_shape_unlocated, opening_shape_gtrsf);
					
			double opening_volume;
			if ( Logger::Verbosity() >= Logger::LOG_WARNING ) {
				opening_volume = shape_volume(opening_shape);
				if ( opening_volume <= ALMOST_ZERO )
					Logger::Message(Logger::LOG_WARNING,"Empty opening for:",entity->entity);
			}

			if (entity_shape.ShapeType() == TopAbs_COMPSOLID) {

				// For compound solids process the subtraction for the constituent
				// solids individually and write the result back as a compound solid.

				TopoDS_CompSolid compound;
				BRep_Builder builder;
				builder.MakeCompSolid(compound);

				TopExp_Explorer exp(entity_shape, TopAbs_SOLID);

				for (; exp.More(); exp.Next()) {

#if OCC_VERSION_HEX < 0x60900
					BRepAlgoAPI_Cut brep_cut(exp.Current(), opening_shape);
#else
					BRepAlgoAPI_Cut brep_cut;
					TopTools_ListOfShape s1s;
					s1s.Append(exp.Current());
					TopTools_ListOfShape s2s;
					s2s.Append(opening_shape);
					brep_cut.SetFuzzyValue(getValue(GV_PRECISION));
					brep_cut.SetArguments(s1s);
					brep_cut.SetTools(s2s);
					brep_cut.Build();
#endif

					bool added = false;
					if ( brep_cut.IsDone() ) {
						TopoDS_Shape brep_cut_result = brep_cut;
						BRepCheck_Analyzer analyser(brep_cut_result);
						bool is_valid = analyser.IsValid() != 0;
						if (is_valid) {
							TopExp_Explorer exp2(brep_cut_result, TopAbs_SOLID);
							for (; exp2.More(); exp2.Next()) {
								builder.Add(compound, exp2.Current());
								added = true;
							}
						}
					}
					if (!added) {
						// Add the original in case subtraction fails
						builder.Add(compound, exp.Current());
					} else {
						Logger::Message(Logger::LOG_ERROR,"Failed to process subtraction:",entity->entity);
					}
				}

				entity_shape = compound;

			} else {
#if OCC_VERSION_HEX < 0x60900
				BRepAlgoAPI_Cut brep_cut(entity_shape,opening_shape);
#else
				BRepAlgoAPI_Cut brep_cut;
				TopTools_ListOfShape s1s;
				s1s.Append(entity_shape);
				TopTools_ListOfShape s2s;
				s2s.Append(opening_shape);
				brep_cut.SetFuzzyValue(getValue(GV_PRECISION));
				brep_cut.SetArguments(s1s);
				brep_cut.SetTools(s2s);
				brep_cut.Build();
#endif

				if ( brep_cut.IsDone() ) {
					TopoDS_Shape brep_cut_result = brep_cut;

					ShapeFix_Shape fix(brep_cut_result);
					try {
						fix.Perform();
						brep_cut_result = fix.Shape();
					} catch (...) {
						Logger::Message(Logger::LOG_WARNING, "Shape healing failed on opening subtraction result", entity->entity);
					}
					
					BRepCheck_Analyzer analyser(brep_cut_result);
					bool is_valid = analyser.IsValid() != 0;
					if ( is_valid ) {
						entity_shape = brep_cut_result;
						if ( Logger::Verbosity() >= Logger::LOG_WARNING ) {
							const double volume_after_subtraction = shape_volume(entity_shape);
							double original_shape_volume = shape_volume(entity_shape);
							if ( ALMOST_THE_SAME(original_shape_volume,volume_after_subtraction) )
								Logger::Message(Logger::LOG_WARNING,"Subtraction yields unchanged volume:",entity->entity);
						}
					} else {
						Logger::Message(Logger::LOG_ERROR,"Invalid result from subtraction:",entity->entity);
					}
				} else {
					Logger::Message(Logger::LOG_ERROR,"Failed to process subtraction:",entity->entity);
				}
			}

		}
		cut_shapes.push_back(IfcGeom::IfcRepresentationShapeItem(entity_shape, &it3->Style()));
	}

	return true;
}

#if OCC_VERSION_HEX < 0x60900
bool IfcGeom::Kernel::convert_openings_fast(const IfcSchema::IfcProduct* entity, const IfcSchema::IfcRelVoidsElement::list::ptr& openings, 
							   const IfcGeom::IfcRepresentationShapeItems& entity_shapes, const gp_Trsf& entity_trsf, IfcGeom::IfcRepresentationShapeItems& cut_shapes) {
	
	// Create a compound of all opening shapes in order to speed up the boolean operations
	TopoDS_Compound opening_compound;
	BRep_Builder builder;
	builder.MakeCompound(opening_compound);

	for ( IfcSchema::IfcRelVoidsElement::list::it it = openings->begin(); it != openings->end(); ++ it ) {
		IfcSchema::IfcRelVoidsElement* v = *it;
		IfcSchema::IfcFeatureElementSubtraction* fes = v->RelatedOpeningElement();
		if ( fes->is(IfcSchema::Type::IfcOpeningElement) ) {
			if (!fes->hasRepresentation()) continue;

			// Convert the IfcRepresentation of the IfcOpeningElement
			gp_Trsf opening_trsf;
			if (fes->hasObjectPlacement()) {
				try {
					convert(fes->ObjectPlacement(),opening_trsf);
				} catch (...) {}
			}

			// Move the opening into the coordinate system of the IfcProduct
			opening_trsf.PreMultiply(entity_trsf.Inverted());

			IfcSchema::IfcProductRepresentation* prodrep = fes->Representation();
			IfcSchema::IfcRepresentation::list::ptr reps = prodrep->Representations();

			IfcGeom::IfcRepresentationShapeItems opening_shapes;
						
			for ( IfcSchema::IfcRepresentation::list::it it2 = reps->begin(); it2 != reps->end(); ++ it2 ) {
				convert_shapes(*it2,opening_shapes);
			}

			for ( unsigned int i = 0; i < opening_shapes.size(); ++ i ) {
				gp_GTrsf gtrsf = opening_shapes[i].Placement();
				gtrsf.PreMultiply(opening_trsf);
				TopoDS_Shape opening_shape = apply_transformation(opening_shapes[i].Shape(), gtrsf);
				builder.Add(opening_compound, opening_shape);
			}

		}
	}

	// Iterate over the shapes of the IfcProduct
	for ( IfcGeom::IfcRepresentationShapeItems::const_iterator it3 = entity_shapes.begin(); it3 != entity_shapes.end(); ++ it3 ) {
		TopoDS_Shape entity_shape_solid;
		const TopoDS_Shape& entity_shape_unlocated = ensure_fit_for_subtraction(it3->Shape(),entity_shape_solid);
		const gp_GTrsf& entity_shape_gtrsf = it3->Placement();
		if (entity_shape_gtrsf.Form() == gp_Other) {
			Logger::Message(Logger::LOG_WARNING, "Applying non uniform transformation to:", entity->entity);
		}
		TopoDS_Shape entity_shape = apply_transformation(entity_shape_unlocated, entity_shape_gtrsf);

		BRepAlgoAPI_Cut brep_cut(entity_shape,opening_compound);

		bool is_valid = false;
		if ( brep_cut.IsDone() ) {
			TopoDS_Shape brep_cut_result = brep_cut;
				
			BRepCheck_Analyzer analyser(brep_cut_result);
			is_valid = analyser.IsValid() != 0;
			if ( is_valid ) {
				cut_shapes.push_back(IfcGeom::IfcRepresentationShapeItem(brep_cut_result, &it3->Style()));
			}
		}
		if ( !is_valid ) {
			// Apparently processing the boolean operation failed or resulted in an invalid result
			// in which case the original shape without the subtractions is returned instead
			// we try convert the openings in the original way, one by one.
			Logger::Message(Logger::LOG_WARNING,"Subtracting combined openings compound failed:",entity->entity);
			return false;
		}
		
	}
	return true;
}
#else
bool IfcGeom::Kernel::convert_openings_fast(const IfcSchema::IfcProduct* entity, const IfcSchema::IfcRelVoidsElement::list::ptr& openings, 
							   const IfcGeom::IfcRepresentationShapeItems& entity_shapes, const gp_Trsf& entity_trsf, IfcGeom::IfcRepresentationShapeItems& cut_shapes) {
	
	TopTools_ListOfShape opening_shapelist;
	
	for ( IfcSchema::IfcRelVoidsElement::list::it it = openings->begin(); it != openings->end(); ++ it ) {
		IfcSchema::IfcRelVoidsElement* v = *it;
		IfcSchema::IfcFeatureElementSubtraction* fes = v->RelatedOpeningElement();
		if ( fes->is(IfcSchema::Type::IfcOpeningElement) ) {
			if (!fes->hasRepresentation()) continue;

			// Convert the IfcRepresentation of the IfcOpeningElement
			gp_Trsf opening_trsf;
			if (fes->hasObjectPlacement()) {
				try {
					convert(fes->ObjectPlacement(),opening_trsf);
				} catch (...) {}
			}

			// Move the opening into the coordinate system of the IfcProduct
			opening_trsf.PreMultiply(entity_trsf.Inverted());

			IfcSchema::IfcProductRepresentation* prodrep = fes->Representation();
			IfcSchema::IfcRepresentation::list::ptr reps = prodrep->Representations();

			IfcGeom::IfcRepresentationShapeItems opening_shapes;
						
			for ( IfcSchema::IfcRepresentation::list::it it2 = reps->begin(); it2 != reps->end(); ++ it2 ) {
				convert_shapes(*it2,opening_shapes);
			}

			for ( unsigned int i = 0; i < opening_shapes.size(); ++ i ) {
				gp_GTrsf gtrsf = opening_shapes[i].Placement();
				gtrsf.PreMultiply(opening_trsf);
				TopoDS_Shape opening_shape = apply_transformation(opening_shapes[i].Shape(), gtrsf);
				opening_shapelist.Append(opening_shape);
			}

		}
	}

	// Iterate over the shapes of the IfcProduct
	for ( IfcGeom::IfcRepresentationShapeItems::const_iterator it3 = entity_shapes.begin(); it3 != entity_shapes.end(); ++ it3 ) {
		TopoDS_Shape entity_shape_solid;
		const TopoDS_Shape& entity_shape_unlocated = ensure_fit_for_subtraction(it3->Shape(),entity_shape_solid);
		const gp_GTrsf& entity_shape_gtrsf = it3->Placement();
		if (entity_shape_gtrsf.Form() == gp_Other) {
			Logger::Message(Logger::LOG_WARNING, "Applying non uniform transformation to:", entity->entity);
		}
		TopoDS_Shape entity_shape = apply_transformation(entity_shape_unlocated, entity_shape_gtrsf);
		
		BRepAlgoAPI_Cut brep_cut;
		TopTools_ListOfShape s1s;
		s1s.Append(entity_shape);
		brep_cut.SetFuzzyValue(getValue(GV_PRECISION));
		brep_cut.SetArguments(s1s);
		brep_cut.SetTools(opening_shapelist);
		brep_cut.Build();

		bool is_valid = false;
		if ( brep_cut.IsDone() ) {
			TopoDS_Shape brep_cut_result = brep_cut;
				
			BRepCheck_Analyzer analyser(brep_cut_result);
			is_valid = analyser.IsValid() != 0;
			if ( is_valid ) {
				cut_shapes.push_back(IfcGeom::IfcRepresentationShapeItem(brep_cut_result, &it3->Style()));
			}
		}
		if ( !is_valid ) {
			// Apparently processing the boolean operation failed or resulted in an invalid result
			// in which case the original shape without the subtractions is returned instead
			// we try convert the openings in the original way, one by one.
			Logger::Message(Logger::LOG_WARNING, "Subtracting combined openings compound failed:", entity->entity);
			return false;
		}
		
	}
	return true;
}
#endif

bool IfcGeom::Kernel::convert_wire_to_face(const TopoDS_Wire& wire, TopoDS_Face& face) {
	BRepBuilderAPI_MakeFace mf(wire, false);
	BRepBuilderAPI_FaceError er = mf.Error();
	if ( er == BRepBuilderAPI_NotPlanar ) {
		ShapeFix_ShapeTolerance FTol;
		FTol.SetTolerance(wire, 0.01, TopAbs_WIRE);
		mf.~BRepBuilderAPI_MakeFace();
		new (&mf) BRepBuilderAPI_MakeFace(wire);
		er = mf.Error();
	}
	if ( er != BRepBuilderAPI_FaceDone ) return false;
	face = mf.Face();
	return true;
}

bool IfcGeom::Kernel::convert_curve_to_wire(const Handle(Geom_Curve)& curve, TopoDS_Wire& wire) {
	try {
		wire = BRepBuilderAPI_MakeWire(BRepBuilderAPI_MakeEdge(curve));
	} catch(...) { return false; }
	return true;
}

bool IfcGeom::Kernel::profile_helper(int numVerts, double* verts, int numFillets, int* filletIndices, double* filletRadii, gp_Trsf2d trsf, TopoDS_Shape& face_shape) {
	TopoDS_Vertex* vertices = new TopoDS_Vertex[numVerts];
	
	for ( int i = 0; i < numVerts; i ++ ) {
		gp_XY xy (verts[2*i],verts[2*i+1]);
		trsf.Transforms(xy);
		vertices[i] = BRepBuilderAPI_MakeVertex(gp_Pnt(xy.X(),xy.Y(),0.0f));
	}

	BRepBuilderAPI_MakeWire w;
	for ( int i = 0; i < numVerts; i ++ )
		w.Add(BRepBuilderAPI_MakeEdge(vertices[i],vertices[(i+1)%numVerts]));

	TopoDS_Face face;
	convert_wire_to_face(w.Wire(),face);

	if ( numFillets && *std::max_element(filletRadii, filletRadii + numFillets) > ALMOST_ZERO ) {
		BRepFilletAPI_MakeFillet2d fillet (face);
		for ( int i = 0; i < numFillets; i ++ ) {
			const double radius = filletRadii[i];
			if ( radius <= ALMOST_ZERO ) continue;
			fillet.AddFillet(vertices[filletIndices[i]],radius);
		}
		fillet.Build();
		if (fillet.IsDone()) {
			face = TopoDS::Face(fillet.Shape());
		} else {
			Logger::Message(Logger::LOG_WARNING, "Failed to process profile fillets");
		}
	}

	face_shape = face;

	delete[] vertices;
	return true;
}
double IfcGeom::Kernel::shape_volume(const TopoDS_Shape& s) {
	GProp_GProps prop;
	BRepGProp::VolumeProperties(s, prop);
	return prop.Mass();
}
double IfcGeom::Kernel::face_area(const TopoDS_Face& f) {
	GProp_GProps prop;
	BRepGProp::SurfaceProperties(f,prop);
	return prop.Mass();
}
bool IfcGeom::Kernel::is_convex(const TopoDS_Wire& wire) {
	for ( TopExp_Explorer exp1(wire,TopAbs_VERTEX); exp1.More(); exp1.Next() ) {
		TopoDS_Vertex V1 = TopoDS::Vertex(exp1.Current());
		gp_Pnt P1 = BRep_Tool::Pnt(V1);
		// Store the neighboring points
		std::vector<gp_Pnt> neighbors;
		for ( TopExp_Explorer exp3(wire,TopAbs_EDGE); exp3.More(); exp3.Next() ) {
			TopoDS_Edge edge = TopoDS::Edge(exp3.Current());
			std::vector<gp_Pnt> edge_points;
			for ( TopExp_Explorer exp2(edge,TopAbs_VERTEX); exp2.More(); exp2.Next() ) {
				TopoDS_Vertex V2 = TopoDS::Vertex(exp2.Current());
				gp_Pnt P2 = BRep_Tool::Pnt(V2);
				edge_points.push_back(P2);
			}
			if ( edge_points.size() != 2 ) continue;
			if ( edge_points[0].IsEqual(P1,getValue(GV_POINT_EQUALITY_TOLERANCE))) neighbors.push_back(edge_points[1]);
			else if ( edge_points[1].IsEqual(P1, getValue(GV_POINT_EQUALITY_TOLERANCE))) neighbors.push_back(edge_points[0]);
		}
		// There should be two of these
		if ( neighbors.size() != 2 ) return false;
		// Now find the non neighboring points
		std::vector<gp_Pnt> non_neighbors;
		for ( TopExp_Explorer exp2(wire,TopAbs_VERTEX); exp2.More(); exp2.Next() ) {
			TopoDS_Vertex V2 = TopoDS::Vertex(exp2.Current());
			gp_Pnt P2 = BRep_Tool::Pnt(V2);
			if ( P1.IsEqual(P2,getValue(GV_POINT_EQUALITY_TOLERANCE)) ) continue;
			bool found = false;
			for( std::vector<gp_Pnt>::const_iterator it = neighbors.begin(); it != neighbors.end(); ++ it ) {
				if ( (*it).IsEqual(P2,getValue(GV_POINT_EQUALITY_TOLERANCE)) ) { found = true; break; }
			}
			if ( ! found ) non_neighbors.push_back(P2);
		}
		// Calculate the angle between the two edges of the vertex
		gp_Dir dir1(neighbors[0].XYZ() - P1.XYZ());
		gp_Dir dir2(neighbors[1].XYZ() - P1.XYZ());
		const double angle = acos(dir1.Dot(dir2)) + 0.0001;
		// Now for the non-neighbors see whether a greater angle can be found with one of the edges
		for ( std::vector<gp_Pnt>::const_iterator it = non_neighbors.begin(); it != non_neighbors.end(); ++ it ) {
			gp_Dir dir3((*it).XYZ() - P1.XYZ());
			const double angle2 = acos(dir3.Dot(dir1));
			const double angle3 = acos(dir3.Dot(dir2));
			if ( angle2 > angle || angle3 > angle ) return false;
		}
	}
	return true;
}
TopoDS_Shape IfcGeom::Kernel::halfspace_from_plane(const gp_Pln& pln,const gp_Pnt& cent) {
	TopoDS_Face face = BRepBuilderAPI_MakeFace(pln).Face();
	return BRepPrimAPI_MakeHalfSpace(face,cent).Solid();
}
gp_Pln IfcGeom::Kernel::plane_from_face(const TopoDS_Face& face) {
	BRepGProp_Face prop(face);
	Standard_Real u1,u2,v1,v2;
	prop.Bounds(u1,u2,v1,v2);
	Standard_Real u = (u1+u2)/2.0;
	Standard_Real v = (v1+v2)/2.0;
	gp_Pnt p;
	gp_Vec n;
	prop.Normal(u,v,p,n);
	return gp_Pln(p,n);
}
gp_Pnt IfcGeom::Kernel::point_above_plane(const gp_Pln& pln, bool agree) {
	if ( agree ) {
		return pln.Location().Translated(pln.Axis().Direction());
	} else {
		return pln.Location().Translated(-pln.Axis().Direction());
	}
}

void IfcGeom::Kernel::apply_tolerance(TopoDS_Shape& s, double t) {
	ShapeFix_ShapeTolerance tol;
	tol.SetTolerance(s, t);
}

void IfcGeom::Kernel::setValue(GeomValue var, double value) {
	switch (var) {
	case GV_DEFLECTION_TOLERANCE:
		deflection_tolerance = value;
		break;
	case GV_WIRE_CREATION_TOLERANCE:
		wire_creation_tolerance = value;
		break;
	case GV_POINT_EQUALITY_TOLERANCE:
		point_equality_tolerance = value;
		break;
	case GV_MAX_FACES_TO_SEW:
		max_faces_to_sew = value;
		break;
	case GV_LENGTH_UNIT:
		ifc_length_unit = value;
		break;
	case GV_PLANEANGLE_UNIT:
		ifc_planeangle_unit = value;
		break;
	case GV_PRECISION:
		modelling_precision = value;
		break;
	case GV_DIMENSIONALITY:
		dimensionality = value;
		break;
	default:
		assert(!"never reach here");
	}
}

double IfcGeom::Kernel::getValue(GeomValue var) const {
	switch (var) {
	case GV_DEFLECTION_TOLERANCE:
		return deflection_tolerance;
	case GV_WIRE_CREATION_TOLERANCE:
		return wire_creation_tolerance;
	case GV_MINIMAL_FACE_AREA:
		// Considering a right-angled triangle, this about the smallest
		// area you can obtain without the vertices being confused.
		return modelling_precision * modelling_precision / 2.;
	case GV_POINT_EQUALITY_TOLERANCE:
		return point_equality_tolerance;
	case GV_MAX_FACES_TO_SEW:
		return max_faces_to_sew;
	case GV_LENGTH_UNIT:
		return ifc_length_unit;
		break;
	case GV_PLANEANGLE_UNIT:
		return ifc_planeangle_unit;
		break;
	case GV_PRECISION:
		return modelling_precision;
		break;
	case GV_DIMENSIONALITY:
		return dimensionality;
		break;
	}
	assert(!"never reach here");
	return 0;
}

// Returns the vertex part of an TopoDS_Edge edge that is not TopoDS_Vertex vertex
TopoDS_Vertex find_other(const TopoDS_Edge& edge, const TopoDS_Vertex& vertex) {
	TopExp_Explorer exp(edge, TopAbs_VERTEX);
	while (exp.More()) {
		if (!exp.Current().IsSame(vertex)) {
			return TopoDS::Vertex(exp.Current());
		}
		exp.Next();
	}
	return TopoDS_Vertex();
}

TopoDS_Edge find_next(const TopTools_IndexedMapOfShape& edge_set, const TopTools_IndexedDataMapOfShapeListOfShape& vertex_to_edges, const TopoDS_Vertex& current, const TopoDS_Edge& previous_edge) {
	const TopTools_ListOfShape& edges = vertex_to_edges.FindFromKey(current);
	TopTools_ListIteratorOfListOfShape eit;
	for (eit.Initialize(edges); eit.More(); eit.Next()) {
		const TopoDS_Edge& edge = TopoDS::Edge(eit.Value());
		if (edge.IsSame(previous_edge)) continue;
		if (edge_set.Contains(edge)) {
			return edge;
		}
	}
	return TopoDS_Edge();
}

bool IfcGeom::Kernel::fill_nonmanifold_wires_with_planar_faces(TopoDS_Shape& shape) {
	BRepOffsetAPI_Sewing sew;
	sew.Add(shape);

	TopTools_IndexedDataMapOfShapeListOfShape edge_to_faces;
	TopTools_IndexedDataMapOfShapeListOfShape vertex_to_edges;
	std::set<int> visited;
	TopTools_IndexedMapOfShape edge_set;

	TopExp::MapShapesAndAncestors (shape, TopAbs_EDGE, TopAbs_FACE, edge_to_faces);

	const int num_edges = edge_to_faces.Extent();
	for (int i = 1; i <= num_edges; ++i) {
		const TopTools_ListOfShape& faces = edge_to_faces.FindFromIndex(i);
		const int count = faces.Extent();
		// Find only the non-manifold edges: Edges that are only part of a
		// single face and therefore part of the wire(s) we want to fill.
		if (count == 1) {
			const TopoDS_Shape& edge = edge_to_faces.FindKey(i);
			TopExp::MapShapesAndAncestors (edge, TopAbs_VERTEX, TopAbs_EDGE, vertex_to_edges);
			edge_set.Add(edge);
		}
	}

	const int num_verts = vertex_to_edges.Extent();
	TopoDS_Vertex first, current;
	TopoDS_Edge previous_edge;

	// Now loop over all the vertices that are part of the wire(s) to be filled
	for (int i = 1; i <= num_verts; ++i) {
		first = current = TopoDS::Vertex(vertex_to_edges.FindKey(i));
		// We keep track of the vertices we already used
		if (visited.find(vertex_to_edges.FindIndex(current)) != visited.end()) {
			continue;
		}
		// Given these vertices, try to find closed loops and create new
		// wires out of them.
		BRepBuilderAPI_MakeWire w;
		for (;;) {
			visited.insert(vertex_to_edges.FindIndex(current));
			// Find the edge that the current vertex is part of and points
			// away from the previous vertex (null for the first vertex).
			TopoDS_Edge edge = find_next(edge_set, vertex_to_edges, current, previous_edge);
			if (edge.IsNull()) {
				return false;
			}
			TopoDS_Vertex other = find_other(edge, current);
			if (other.IsNull()) {
				// Dealing with a conical edge probably, for some reason
				// this works better than adding the edge directly.
				double u1, u2;
				Handle(Geom_Curve) crv = BRep_Tool::Curve(edge, u1, u2);
				w.Add(BRepBuilderAPI_MakeEdge(crv, u1, u2));
				break;
			} else {
				w.Add(edge);
			}
			// See if the starting point of this loop has been reached. Note that
			// additional wires after this one potentially will be created.
			if (other.IsSame(first)) {
				break;
			}
			previous_edge = edge;
			current = other;
		}
		sew.Add(BRepBuilderAPI_MakeFace(w));
		previous_edge.Nullify();
	}
		
	sew.Perform();
	shape = sew.SewedShape();

	try {
		ShapeFix_Solid solid;
		solid.LimitTolerance(getValue(GV_POINT_EQUALITY_TOLERANCE));
		shape = solid.SolidFromShell(TopoDS::Shell(shape));
	} catch(...) {}

	return true;
}

bool IfcGeom::Kernel::flatten_shape_list(const IfcGeom::IfcRepresentationShapeItems& shapes, TopoDS_Shape& result, bool fuse) {
	TopoDS_Compound compound;
	BRep_Builder builder;
	builder.MakeCompound(compound);

	result = TopoDS_Shape();
			
	for ( IfcGeom::IfcRepresentationShapeItems::const_iterator it = shapes.begin(); it != shapes.end(); ++ it ) {
		TopoDS_Shape merged;
		const TopoDS_Shape& s = it->Shape();
		if (fuse) {
			ensure_fit_for_subtraction(s, merged);
		} else {
			merged = s;
		}
		const gp_GTrsf& trsf = it->Placement();
		const TopoDS_Shape moved_shape = apply_transformation(merged, trsf);

		if (shapes.size() == 1) {
			result = moved_shape;
			const double precision = getValue(GV_PRECISION);
			apply_tolerance(result, precision);
			return true;
		}

		if (fuse) {
			if (result.IsNull()) {
				result = moved_shape;
			} else {
				BRepAlgoAPI_Fuse brep_fuse(result, moved_shape);
				if ( brep_fuse.IsDone() ) {
					TopoDS_Shape fused = brep_fuse;

					ShapeFix_Shape fix(result);
					fix.Perform();
					result = fix.Shape();
		
					bool is_valid = BRepCheck_Analyzer(result).IsValid() != 0;
					if ( is_valid ) {
						result = fused;
					} 
				}
			}
		} else {
			builder.Add(compound,moved_shape);
		}
	}

	if (!fuse) {
		result = compound;
	}

	const bool success = !result.IsNull();
	if (success) {
		const double precision = getValue(GV_PRECISION);
		apply_tolerance(result, precision);
	}

	return success;
}
	
void IfcGeom::Kernel::remove_duplicate_points_from_loop(TColgp_SequenceOfPnt& polygon, bool closed, double tol) {
	if (tol <= 0.) tol = getValue(GV_POINT_EQUALITY_TOLERANCE);
	tol *= tol;

	for (;;) {
		bool removed = false;
		int n = polygon.Length() - (closed ? 0 : 1);
		for (int i = 1; i <= n; ++i) {
			// wrap around to the first point in case of a closed loop
			int j = (i % polygon.Length()) + 1;
			double dist = polygon.Value(i).SquareDistance(polygon.Value(j));
			if (dist < tol) {
				// do not remove the first or last point to
				// maintain connectivity with other wires
				if ((closed && j == 1) || (!closed && j == n)) polygon.Remove(i);
				else polygon.Remove(j);
				removed = true;
				break;
			}
		}
		if (!removed) break;
	}
}

void IfcGeom::Kernel::remove_collinear_points_from_loop(TColgp_SequenceOfPnt& polygon, bool closed, double tol) {
	if (tol <= 0.) tol = getValue(GV_POINT_EQUALITY_TOLERANCE);
	const int start = closed ? 1 : 2;
	const int end = polygon.Length() - (closed ? 0 : 1);
	std::vector<bool> to_remove(polygon.Length(), false);
	for (int i = start; i <= end; ++i) {
		const gp_Pnt& a = polygon.Value(((i - 2 + polygon.Length()) % polygon.Length()) + 1);
		const gp_Pnt& b = polygon.Value(i);
		const gp_Pnt& c = polygon.Value((i % polygon.Length()) + 1);
		const gp_Vec d1 = c.XYZ() - a.XYZ();
		const gp_Vec d2 = b.XYZ() - a.XYZ();
		const double dt = d2.Dot(d1) / d1.Dot(d1);
		const gp_Vec d3 = d1.Scaled(dt);
		const gp_Pnt b2 = a.XYZ() + d3.XYZ();
		if (b.Distance(b2) < tol) {
			to_remove[i-1] = true;
		}
	}
	for (int i = (int) to_remove.size() - 1; i >= 0; --i) {
		if (to_remove[i]) {
			polygon.Remove(i+1);
		}
	}
}

bool IfcGeom::Kernel::wire_to_sequence_of_point(const TopoDS_Wire& w, TColgp_SequenceOfPnt& p) {
	TopExp_Explorer exp(w, TopAbs_EDGE);
	for (; exp.More(); exp.Next()) {
		double a, b;
		Handle_Geom_Curve crv = BRep_Tool::Curve(TopoDS::Edge(exp.Current()), a, b);
		if (crv->DynamicType() != STANDARD_TYPE(Geom_Line)) {
			return false;
		}
	}

	exp.ReInit();

	int i = 0;
	for (; exp.More(); exp.Next(), ++i) {
		TopoDS_Vertex v1, v2;
		TopExp::Vertices(TopoDS::Edge(exp.Current()), v1, v2, true);
		if (exp.More()) {
			if (i == 0) {
				p.Append(BRep_Tool::Pnt(v1));
			}
			p.Append(BRep_Tool::Pnt(v2));
		}
	}

	return true;
}

void IfcGeom::Kernel::sequence_of_point_to_wire(const TColgp_SequenceOfPnt& p, TopoDS_Wire& w, bool close) {
	BRepBuilderAPI_MakePolygon builder;
	for (int i = 1; i <= p.Length(); ++i) {
		builder.Add(p.Value(i));
	}
	if (close) {
		builder.Close();
	}
	w = builder.Wire();	
}

IfcSchema::IfcRelVoidsElement::list::ptr IfcGeom::Kernel::find_openings(IfcSchema::IfcProduct* product) {
	
	IfcSchema::IfcRelVoidsElement::list::ptr openings(new IfcSchema::IfcRelVoidsElement::list);
	if ( product->is(IfcSchema::Type::IfcElement) && !product->is(IfcSchema::Type::IfcOpeningElement) ) {
		IfcSchema::IfcElement* element = (IfcSchema::IfcElement*)product;
		openings = element->HasOpenings();
	}

	// Is the IfcElement a decomposition of an IfcElement with any IfcOpeningElements?
	IfcSchema::IfcObjectDefinition* obdef = product->as<IfcSchema::IfcObjectDefinition>();
	for (;;) {
#ifdef USE_IFC4
		IfcSchema::IfcRelAggregates::list::ptr decomposes = obdef->Decomposes();
#else
		IfcSchema::IfcRelDecomposes::list::ptr decomposes = obdef->Decomposes();
#endif
		if (decomposes->size() != 1) break;
		IfcSchema::IfcObjectDefinition* rel_obdef = (*decomposes->begin())->RelatingObject();
		if ( rel_obdef->is(IfcSchema::Type::IfcElement) && !rel_obdef->is(IfcSchema::Type::IfcOpeningElement) ) {
			IfcSchema::IfcElement* element = (IfcSchema::IfcElement*)rel_obdef;
			openings->push(element->HasOpenings());
		}

		obdef = rel_obdef;
	}

	return openings;
}

template <typename P>
IfcGeom::BRepElement<P>* IfcGeom::Kernel::create_brep_for_representation_and_product(
    const IteratorSettings& settings, IfcSchema::IfcRepresentation* representation, IfcSchema::IfcProduct* product)
{
	IfcGeom::Representation::BRep* shape;
	IfcGeom::IfcRepresentationShapeItems shapes, shapes2;

	if ( !convert_shapes(representation, shapes) ) {
		return 0;
	}

	if (settings.get(IteratorSettings::APPLY_LAYERSETS)) {
		TopoDS_Shape merge;
		if (flatten_shape_list(shapes, merge, false)) {
			if (count(merge, TopAbs_FACE) > 0) {
				std::vector<double> thickness;
				std::vector<Handle_Geom_Surface> layers;
				std::vector< std::vector<Handle_Geom_Surface> > folded_layers;
				std::vector<const SurfaceStyle*> styles;
				if (convert_layerset(product, layers, styles, thickness)) {
					if (product->as<IfcSchema::IfcWall>() && fold_layers(product->as<IfcSchema::IfcWall>(), shapes, layers, thickness, folded_layers)) {
						if (apply_folded_layerset(shapes, folded_layers, styles, shapes2)) {
							std::swap(shapes, shapes2);
						}
					} else {
						if (apply_layerset(shapes, layers, styles, shapes2)) {
							std::swap(shapes, shapes2);
						}
					}
				}
			}
		}
	}

	int parent_id = -1;
	try {
		IfcSchema::IfcObjectDefinition* parent_object = get_decomposing_entity(product);
		if (parent_object) {
			parent_id = parent_object->entity->id();
		}
	} catch (...) {}
		
	const std::string name = product->hasName() ? product->Name() : "";
	const std::string guid = product->GlobalId();
		
	gp_Trsf trsf;
	try {
		convert(product->ObjectPlacement(),trsf);
	} catch (...) {}

	// Does the IfcElement have any IfcOpenings?
	// Note that openings for IfcOpeningElements are not processed
	IfcSchema::IfcRelVoidsElement::list::ptr openings = find_openings(product);

	const std::string product_type = IfcSchema::Type::ToString(product->type());
	ElementSettings element_settings(settings, getValue(GV_LENGTH_UNIT), product_type);

    if (!settings.get(IfcGeom::IteratorSettings::DISABLE_OPENING_SUBTRACTIONS) && openings && openings->size()) {
		IfcGeom::IfcRepresentationShapeItems opened_shapes;
		try {
#if OCC_VERSION_HEX < 0x60900
            const bool faster_booleans = settings.get(IteratorSettings::FASTER_BOOLEANS);
#else
			const bool faster_booleans = true;
#endif
			if (faster_booleans) {
				bool succes = convert_openings_fast(product,openings,shapes,trsf,opened_shapes);
				if ( ! succes ) {
					opened_shapes.clear();
					convert_openings(product,openings,shapes,trsf,opened_shapes);
				}
			} else {
				convert_openings(product,openings,shapes,trsf,opened_shapes);
			}
		} catch(...) { 
			Logger::Message(Logger::LOG_ERROR,"Error processing openings for:",product->entity); 
		}
        if (settings.get(IteratorSettings::USE_WORLD_COORDS)) {
			for ( IfcGeom::IfcRepresentationShapeItems::iterator it = opened_shapes.begin(); it != opened_shapes.end(); ++ it ) {
				it->prepend(trsf);
			}
			trsf = gp_Trsf();
		}
		shape = new IfcGeom::Representation::BRep(element_settings, representation->entity->id(), opened_shapes);
    } else if (settings.get(IteratorSettings::USE_WORLD_COORDS)) {
		for ( IfcGeom::IfcRepresentationShapeItems::iterator it = shapes.begin(); it != shapes.end(); ++ it ) {
			it->prepend(trsf);
		}
		trsf = gp_Trsf();
		shape = new IfcGeom::Representation::BRep(element_settings, representation->entity->id(), shapes);
	} else {
		shape = new IfcGeom::Representation::BRep(element_settings, representation->entity->id(), shapes);
	}

	std::string context_string = "";
	if (representation->hasRepresentationIdentifier()) {
		context_string = representation->RepresentationIdentifier();
	} else if (representation->ContextOfItems()->hasContextType()) {
		context_string = representation->ContextOfItems()->ContextType();
	}

	return new BRepElement<P>(
		product->entity->id(),
		parent_id,
		name, 
		product_type,
		guid,
		context_string,
		trsf,
		boost::shared_ptr<IfcGeom::Representation::BRep>(shape)
	);
}

template <typename P>
IfcGeom::BRepElement<P>* IfcGeom::Kernel::create_brep_for_processed_representation(
    const IteratorSettings& /*settings*/, IfcSchema::IfcRepresentation* representation, IfcSchema::IfcProduct* product,
    IfcGeom::BRepElement<P>* brep)
{
	int parent_id = -1;
	try {
		IfcSchema::IfcObjectDefinition* parent_object = get_decomposing_entity(product);
		if (parent_object) {
			parent_id = parent_object->entity->id();
		}
	} catch (...) {}
		
	const std::string name = product->hasName() ? product->Name() : "";
	const std::string guid = product->GlobalId();
		
	gp_Trsf trsf;
	try {
		convert(product->ObjectPlacement(),trsf);
	} catch (...) {}

	std::string context_string = "";
	if (representation->hasRepresentationIdentifier()) {
		context_string = representation->RepresentationIdentifier();
	} else if (representation->ContextOfItems()->hasContextType()) {
		context_string = representation->ContextOfItems()->ContextType();
	}

	const std::string product_type = IfcSchema::Type::ToString(product->type());

	return new BRepElement<P>(
		product->entity->id(),
		parent_id,
		name, 
		product_type,
		guid,
		context_string,
		trsf,
		brep->geometry_pointer()
	);
}

IfcSchema::IfcObjectDefinition* IfcGeom::Kernel::get_decomposing_entity(IfcSchema::IfcProduct* product) {
	IfcSchema::IfcObjectDefinition* parent = 0;

	// In case of an opening element, parent to the RelatingBuildingElement
	if ( product->is(IfcSchema::Type::IfcOpeningElement ) ) {
		IfcSchema::IfcOpeningElement* opening = (IfcSchema::IfcOpeningElement*)product;
		IfcSchema::IfcRelVoidsElement::list::ptr voids = opening->VoidsElements();
		if ( voids->size() ) {
			IfcSchema::IfcRelVoidsElement* ifc_void = *voids->begin();
			parent = ifc_void->RelatingBuildingElement();
		}
	} else if ( product->is(IfcSchema::Type::IfcElement ) ) {
		IfcSchema::IfcElement* element = (IfcSchema::IfcElement*)product;
		IfcSchema::IfcRelFillsElement::list::ptr fills = element->FillsVoids();
		// Incase of a RelatedBuildingElement parent to the opening element
		if ( fills->size() ) {
			for ( IfcSchema::IfcRelFillsElement::list::it it = fills->begin(); it != fills->end(); ++ it ) {
				IfcSchema::IfcRelFillsElement* fill = *it;
				IfcSchema::IfcObjectDefinition* ifc_objectdef = fill->RelatingOpeningElement();
				if ( product == ifc_objectdef ) continue;
				parent = ifc_objectdef;
			}
		} 
		// Else simply parent to the containing structure
		if (!parent) {
			IfcSchema::IfcRelContainedInSpatialStructure::list::ptr parents = element->ContainedInStructure();
			if ( parents->size() ) {
				IfcSchema::IfcRelContainedInSpatialStructure* container = *parents->begin();
				parent = container->RelatingStructure();
			}
		}
	}
	// Parent decompositions to the RelatingObject
	if (!parent) {
		IfcEntityList::ptr parents = product->entity->getInverse(IfcSchema::Type::IfcRelAggregates, -1);
		parents->push(product->entity->getInverse(IfcSchema::Type::IfcRelNests, -1));
		for ( IfcEntityList::it it = parents->begin(); it != parents->end(); ++ it ) {
			IfcSchema::IfcRelDecomposes* decompose = (IfcSchema::IfcRelDecomposes*)*it;
			IfcSchema::IfcObjectDefinition* ifc_objectdef;
#ifdef USE_IFC4
			if (decompose->is(IfcSchema::Type::IfcRelAggregates)) {
				ifc_objectdef = ((IfcSchema::IfcRelAggregates*)decompose)->RelatingObject();
			} else {
				continue;
			}
#else
			ifc_objectdef = decompose->RelatingObject();
#endif
			if ( product == ifc_objectdef ) continue;
			parent = ifc_objectdef;
		}
	}
	return parent;
}

template IFC_GEOM_API IfcGeom::BRepElement<float>* IfcGeom::Kernel::create_brep_for_representation_and_product<float>(
    const IteratorSettings& settings, IfcSchema::IfcRepresentation* representation, IfcSchema::IfcProduct* product);
template IFC_GEOM_API IfcGeom::BRepElement<double>* IfcGeom::Kernel::create_brep_for_representation_and_product<double>(
    const IteratorSettings& settings, IfcSchema::IfcRepresentation* representation, IfcSchema::IfcProduct* product);

template IFC_GEOM_API IfcGeom::BRepElement<float>* IfcGeom::Kernel::create_brep_for_processed_representation<float>(
    const IteratorSettings& settings, IfcSchema::IfcRepresentation* representation, IfcSchema::IfcProduct* product, IfcGeom::BRepElement<float>* brep);
template IFC_GEOM_API IfcGeom::BRepElement<double>* IfcGeom::Kernel::create_brep_for_processed_representation<double>(
    const IteratorSettings& settings, IfcSchema::IfcRepresentation* representation, IfcSchema::IfcProduct* product, IfcGeom::BRepElement<double>* brep);

std::pair<std::string, double> IfcGeom::Kernel::initializeUnits(IfcSchema::IfcUnitAssignment* unit_assignment) {
	// Set default units, set length to meters, angles to undefined
	setValue(IfcGeom::Kernel::GV_LENGTH_UNIT, 1.0);
	setValue(IfcGeom::Kernel::GV_PLANEANGLE_UNIT, -1.0);

	std::string unit_name = "METER";
	double unit_magnitude = 1.;

	try {
		IfcEntityList::ptr units = unit_assignment->Units();
		if (!units || !units->size()) {
			Logger::Message(Logger::LOG_ERROR, "No unit information found");
		} else {
			for (IfcEntityList::it it = units->begin(); it != units->end(); ++it) {
				IfcUtil::IfcBaseClass* base = *it;
				if (base->is(IfcSchema::Type::IfcNamedUnit)) {
					IfcSchema::IfcNamedUnit* named_unit = base->as<IfcSchema::IfcNamedUnit>();
					if (named_unit->UnitType() == IfcSchema::IfcUnitEnum::IfcUnit_LENGTHUNIT ||
						named_unit->UnitType() == IfcSchema::IfcUnitEnum::IfcUnit_PLANEANGLEUNIT)
					{
						std::string current_unit_name;
						const double current_unit_magnitude = IfcParse::get_SI_equivalent(named_unit);
						if (current_unit_magnitude != 0.) {
							if (named_unit->is(IfcSchema::Type::IfcConversionBasedUnit)) {
								IfcSchema::IfcConversionBasedUnit* u = (IfcSchema::IfcConversionBasedUnit*)base;
								current_unit_name = u->Name();
							} else if (named_unit->is(IfcSchema::Type::IfcSIUnit)) {
								IfcSchema::IfcSIUnit* si_unit = named_unit->as<IfcSchema::IfcSIUnit>();
								if (si_unit->hasPrefix()) {
									current_unit_name = IfcSchema::IfcSIPrefix::ToString(si_unit->Prefix()) + unit_name;
								}
								current_unit_name += IfcSchema::IfcSIUnitName::ToString(si_unit->Name());
							}
							if (named_unit->UnitType() == IfcSchema::IfcUnitEnum::IfcUnit_LENGTHUNIT) {
								unit_name = current_unit_name;
								unit_magnitude = current_unit_magnitude;
								setValue(IfcGeom::Kernel::GV_LENGTH_UNIT, current_unit_magnitude);
							} else {
								setValue(IfcGeom::Kernel::GV_PLANEANGLE_UNIT, current_unit_magnitude);
							}
						}
					}
				}
			}
		}
	} catch (const IfcParse::IfcException& ex) {
		std::stringstream ss;
		ss << "Failed to determine unit information '" << ex.what() << "'";
		Logger::Message(Logger::LOG_ERROR, ss.str());
	}

	return std::pair<std::string, double>(unit_name, unit_magnitude);
}

bool IfcGeom::Kernel::convert_layerset(const IfcSchema::IfcProduct* product, std::vector<Handle_Geom_Surface>& surfaces, std::vector<const SurfaceStyle*>& styles, std::vector<double>& thicknesses) {
	IfcSchema::IfcMaterialLayerSetUsage* usage = 0;
	Handle_Geom_Surface reference_surface;

	IfcSchema::IfcRelAssociates::list::ptr associations = product->HasAssociations();
	for (IfcSchema::IfcRelAssociates::list::it it = associations->begin(); it != associations->end(); ++it) {
		IfcSchema::IfcRelAssociatesMaterial* associates_material = (**it).as<IfcSchema::IfcRelAssociatesMaterial>();
		if (associates_material) {
			usage = associates_material->RelatingMaterial()->as<IfcSchema::IfcMaterialLayerSetUsage>();
			break;
		}
	}

	if (!usage) {
		return false;
	}

	IfcSchema::IfcRepresentation* body_representation = find_representation(product, "Body");
	IfcSchema::IfcRepresentation* axis_representation = find_representation(product, "Axis");

	if (product->is(IfcSchema::Type::IfcWall)) {
		if (!axis_representation) {
			Logger::Message(Logger::LOG_WARNING, "No axis representation for:", product->entity);
			return false;
		}

		IfcRepresentationShapeItems axis_items;
		{
			Kernel temp = *this;
			temp.setValue(GV_DIMENSIONALITY, -1.);
			temp.convert_shapes(axis_representation, axis_items);
		}

		TopoDS_Shape axis_shape;
		flatten_shape_list(axis_items, axis_shape, false);

		TopExp_Explorer exp(axis_shape, TopAbs_EDGE);
		TopoDS_Edge axis_edge;
		int edge_count = 0;

		if (exp.More()) {
			axis_edge = TopoDS::Edge(exp.Current());
			++ edge_count;
		} else {
			Logger::Message(Logger::LOG_WARNING, "No edge found in axis representation:", product->entity);
			return false;
		}

		double u1, u2;
		Handle_Geom_Curve axis_curve = BRep_Tool::Curve(axis_edge, u1, u2);

		if (true) { /**< @todo Why always true? */
			if (axis_curve->DynamicType() == STANDARD_TYPE(Geom_Line)) {
				Handle_Geom_Line axis_line = Handle_Geom_Line::DownCast(axis_curve);
				reference_surface = new Geom_Plane(axis_line->Lin().Location(), axis_line->Lin().Direction() ^ gp::DZ());
			} else if (axis_curve->DynamicType() == STANDARD_TYPE(Geom_Circle)) {
				Handle_Geom_Circle axis_line = Handle_Geom_Circle::DownCast(axis_curve);
				reference_surface = new Geom_CylindricalSurface(axis_line->Position(), axis_line->Radius());
			} else {
				Logger::Message(Logger::LOG_ERROR, "Unsupported underlying curve of Axis representation:", product->entity);
				return false;
			}
		} else {
			// Unfortunately this does not work when its intersection
			// is calculated later on when the layerset is applied.
			reference_surface = new Geom_SurfaceOfLinearExtrusion(axis_curve, gp::DZ());
		}
		
	} else {
		IfcSchema::IfcExtrudedAreaSolid::list::ptr extrusions = body_representation->entity->file->traverse(body_representation)->as<IfcSchema::IfcExtrudedAreaSolid>();
		
		if (extrusions->size() != 1) {
			Logger::Message(Logger::LOG_WARNING, "No single extrusion found in body representation for:", product->entity);
			return false;
		}

		IfcSchema::IfcExtrudedAreaSolid* extrusion = *extrusions->begin();

		gp_Trsf extrusion_position;
		if (!convert(extrusion->Position(), extrusion_position)) {
			Logger::Message(Logger::LOG_ERROR, "Failed to convert placement for extrusion of:", product->entity);
			return false;
		}

		gp_Dir extrusion_direction;
		if (!convert(extrusion->ExtrudedDirection(), extrusion_direction)) {
			Logger::Message(Logger::LOG_ERROR, "Failed to convert direction for extrusion of:", product->entity);
			return false;
		}

		reference_surface = new Geom_Plane(extrusion_position.TranslationPart(), extrusion_direction);
	}

	const IfcSchema::IfcMaterialLayerSet* layerset = usage->ForLayerSet();
	const bool positive = usage->DirectionSense() == IfcSchema::IfcDirectionSenseEnum::IfcDirectionSense_POSITIVE;
	double offset = usage->OffsetFromReferenceLine() * getValue(GV_LENGTH_UNIT);

	IfcSchema::IfcMaterialLayer::list::ptr material_layers = layerset->MaterialLayers();

	surfaces.push_back(new Geom_OffsetSurface(reference_surface, -offset));

	for (IfcSchema::IfcMaterialLayer::list::it it = material_layers->begin(); it != material_layers->end(); ++it) {
		styles.push_back(get_style((*it)->Material()));

		double thickness = (*it)->LayerThickness() * getValue(GV_LENGTH_UNIT);

		thicknesses.push_back(thickness);
		
		if (!positive) {
			thickness *= -1;
		}

		offset += thickness;

		if (fabs(offset) < 1.e-7) {
			surfaces.push_back(reference_surface);
		} else {
			surfaces.push_back(new Geom_OffsetSurface(reference_surface, -offset));
		}
	}

	if (positive) {
		std::reverse(surfaces.begin(), surfaces.end());
	}

	return true;
}

const Handle_Geom_Curve IfcGeom::Kernel::intersect(const Handle_Geom_Surface& a, const Handle_Geom_Surface& b) {
	GeomAPI_IntSS x(a, b, 1.e-7);
	if (x.IsDone() && x.NbLines() == 1) {
		return x.Line(1);
	} else {
		return Handle_Geom_Curve();
	}
}

const Handle_Geom_Curve IfcGeom::Kernel::intersect(const Handle_Geom_Surface& a, const TopoDS_Face& b) {
	return intersect(a, BRep_Tool::Surface(b));
}

const Handle_Geom_Curve IfcGeom::Kernel::intersect(const TopoDS_Face& a, const Handle_Geom_Surface& b) {
	return intersect(BRep_Tool::Surface(a), b);
}

bool IfcGeom::Kernel::intersect(const Handle_Geom_Curve& a, const Handle_Geom_Surface& b, gp_Pnt& p) {
	GeomAPI_IntCS x(a, b);
	if (x.IsDone() && x.NbPoints() == 1) {
		p = x.Point(1);
		return true;
	} else {
		return false;
	}
}

bool IfcGeom::Kernel::intersect(const Handle_Geom_Curve& a, const TopoDS_Face& b, gp_Pnt &c) {
	return intersect(a, BRep_Tool::Surface(b), c);
}

bool IfcGeom::Kernel::intersect(const Handle_Geom_Curve& a, const TopoDS_Shape& b, std::vector<gp_Pnt>& out) {
	TopExp_Explorer exp(b, TopAbs_FACE);
	gp_Pnt p;
	for (; exp.More(); exp.Next()) {
		if (intersect(a, TopoDS::Face(exp.Current()), p)) {
			out.push_back(p);
		}
	}
	return !out.empty();
}

bool IfcGeom::Kernel::intersect(const Handle_Geom_Surface& a, const TopoDS_Shape& b, std::vector< std::pair<Handle_Geom_Surface, Handle_Geom_Curve> >& out) {
	TopExp_Explorer exp(b, TopAbs_FACE);
	for (; exp.More(); exp.Next()) {
		const TopoDS_Face& f = TopoDS::Face(exp.Current());
		const Handle_Geom_Surface& s = BRep_Tool::Surface(f);
		Handle_Geom_Curve crv = intersect(a, s);
		if (!crv.IsNull()) {
			out.push_back(std::make_pair(s, crv));
		}
	}
	return !out.empty();
}

bool IfcGeom::Kernel::closest(const gp_Pnt& a, const std::vector<gp_Pnt>& b, gp_Pnt& c) {
	double minimal_distance = std::numeric_limits<double>::infinity();
	for (std::vector<gp_Pnt>::const_iterator it = b.begin(); it != b.end(); ++it) {
		const double d = a.Distance(*it);
		if (d < minimal_distance) {
			minimal_distance = d;
			c = *it;
		}
	}
	return minimal_distance != std::numeric_limits<double>::infinity();
}

bool IfcGeom::Kernel::project(const Handle_Geom_Curve& crv, const gp_Pnt& pt, gp_Pnt& p, double& u, double& d) {
	ShapeAnalysis_Curve sac;
	sac.Project(crv, pt, 1e-3, p, u, false);
	d = pt.Distance(p);
	return true;
}

int IfcGeom::Kernel::count(const TopoDS_Shape& s, TopAbs_ShapeEnum t) {
	int i = 0;
	TopExp_Explorer exp(s, t);
	for (; exp.More(); exp.Next()) {
		++i;
	}
	return i;
}

bool IfcGeom::Kernel::find_wall_end_points(const IfcSchema::IfcWall* wall, gp_Pnt& start, gp_Pnt& end) {
	IfcSchema::IfcRepresentation* axis_representation = find_representation(wall, "Axis");
	if (!axis_representation) {
		return false;
	}
		
	IfcRepresentationShapeItems items;
	{
		Kernel temp = *this;
		temp.setValue(GV_DIMENSIONALITY, -1.);
		temp.convert_shapes(axis_representation, items);
	}

	TopoDS_Vertex a, b;
	for (IfcRepresentationShapeItems::const_iterator it = items.begin(); it != items.end(); ++it) {
		TopExp_Explorer exp(it->Shape(), TopAbs_VERTEX);
		for (; exp.More(); exp.Next()) {
			b = TopoDS::Vertex(exp.Current());
			if (a.IsNull()) {
				a = b;
			}				
		}
	}
	
	if (a.IsNull() || b.IsNull()) {
		return false;
	}

	start = BRep_Tool::Pnt(a);
	end = BRep_Tool::Pnt(b);

	return true;
}

bool IfcGeom::Kernel::fold_layers(const IfcSchema::IfcWall* wall, const IfcRepresentationShapeItems& items, const std::vector<Handle_Geom_Surface>& surfaces, const std::vector<double>& thicknesses, std::vector< std::vector<Handle_Geom_Surface> >& result) {
	bool folds_made = false;
	
	IfcSchema::IfcRelConnectsPathElements::list::ptr connections(new IfcSchema::IfcRelConnectsPathElements::list);
	connections->push(wall->ConnectedFrom()->as<IfcSchema::IfcRelConnectsPathElements>());
	connections->push(  wall->ConnectedTo()->as<IfcSchema::IfcRelConnectsPathElements>());

	typedef std::vector<Handle_Geom_Surface> surfaces_t;
	typedef std::pair<Handle_Geom_Surface, Handle_Geom_Curve> curve_on_surface;
	typedef std::vector<curve_on_surface> curves_on_surfaces_t;
	typedef std::vector< std::pair< std::pair<IfcSchema::IfcConnectionTypeEnum::IfcConnectionTypeEnum, IfcSchema::IfcConnectionTypeEnum::IfcConnectionTypeEnum>, const IfcSchema::IfcProduct*> > endpoint_connections_t;
	typedef std::vector< std::vector<Handle_Geom_Surface> > result_t;
	endpoint_connections_t endpoint_connections;

	for (IfcSchema::IfcRelConnectsPathElements::list::it it = connections->begin(); it != connections->end(); ++it) {
		IfcSchema::IfcRelConnectsPathElements* connection = *it;
		IfcSchema::IfcConnectionTypeEnum::IfcConnectionTypeEnum own_type = connection->RelatedElement() == wall
			? connection->RelatedConnectionType()
			: connection->RelatingConnectionType();
		IfcSchema::IfcConnectionTypeEnum::IfcConnectionTypeEnum other_type = connection->RelatedElement() == wall
			? connection->RelatingConnectionType()
			: connection->RelatedConnectionType();
		if (other_type != IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATPATH && 
		   (own_type == IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATEND ||
			own_type == IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATSTART))
		{
			IfcSchema::IfcElement* other = connection->RelatedElement() == wall
				? connection->RelatingElement()
				: connection->RelatedElement();
			if (other->as<IfcSchema::IfcWall>()) {
				endpoint_connections.push_back(std::make_pair(std::make_pair(own_type, other_type), other));
			}
		}
	}

	if (endpoint_connections.size() == 0) {
		return false;
	}

	int connection_type_count[2] = {0,0};
	for (endpoint_connections_t::const_iterator it = endpoint_connections.begin(); it != endpoint_connections.end(); ++it) {
		const int idx = it->first.first == IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATSTART;
		connection_type_count[idx] ++;
	}

	gp_Trsf local;
	if (!convert(wall->ObjectPlacement(), local)) {
		return false;
	}
	local.Invert();

	{
		// Copy the unfolded surfaces
		result.resize(surfaces.size());
		std::vector< std::vector<Handle_Geom_Surface> >::iterator result_it = result.begin() + 1;
		std::vector<Handle_Geom_Surface>::const_iterator input_it = surfaces.begin() + 1;
		for(; input_it != surfaces.end() - 1; ++result_it, ++input_it) {
			result_it->push_back(*input_it);
		}
	}

	gp_Pnt own_axis_start, own_axis_end;
	find_wall_end_points(wall, own_axis_start, own_axis_end);

	for (int idx = 0; idx < 2; ++idx) {
		if (connection_type_count[idx] <= 1) {
			continue;
		}
		
		/*
		IfcSchema::IfcConnectionTypeEnum::IfcConnectionTypeEnum connection_type = idx == 1
			? IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATSTART
			: IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATEND;
		*/

		std::set<const IfcSchema::IfcProduct*> others;
		endpoint_connections_t::iterator it = endpoint_connections.begin();
		while (it != endpoint_connections.end()) {
			const IfcSchema::IfcProduct* other = it->second;
			if (others.find(other) != others.end()) {
				it = endpoint_connections.erase(it);
				-- connection_type_count[idx];
			} else {
				others.insert(other);
				++it;
			}
		}

		/*
		Additionally one could check whether the end points are of the wall are really ~1 LayerThickness away from each other
		for (endpoint_connections_t::const_iterator it = endpoint_connections.begin(); it != endpoint_connections.end(); ++it) {
			IfcSchema::IfcConnectionTypeEnum::IfcConnectionTypeEnum relating_connection_type = it->first.first;
			IfcSchema::IfcConnectionTypeEnum::IfcConnectionTypeEnum related_connection_type = it->first.second;

			if (connection_type != relating_connection_type) {
				continue;
			}

			gp_Pnt other_axis_start, other_axis_end;
			find_wall_end_points(it->second->as<IfcSchema::IfcWall>(), other_axis_start, other_axis_end);

			gp_Trsf other;
			if (!convert(it->second->ObjectPlacement(), other)) {
				continue;
			}

			other.Transforms(other_axis_start.ChangeCoord());
			local.Transforms(other_axis_start.ChangeCoord());
			other.Transforms(other_axis_end.ChangeCoord());
			local.Transforms(other_axis_end.ChangeCoord());

			const gp_Pnt& a = relating_connection_type == IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATSTART
				? own_axis_start
				: own_axis_end;

			const gp_Pnt& b = related_connection_type == IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATSTART
				? other_axis_start
				: other_axis_end;

			const double d = a.Distance(b);
		}
		*/
	}

	for (endpoint_connections_t::const_iterator it = endpoint_connections.begin(); it != endpoint_connections.end(); ++it) {
		IfcSchema::IfcConnectionTypeEnum::IfcConnectionTypeEnum connection_type = it->first.first;

		// If more than one wall connects to this start/end -point assume layers do not need to be folded
		const int idx = connection_type == IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATSTART;
		if (connection_type_count[idx] > 1) continue;

		const gp_Pnt& own_end_point = connection_type == IfcSchema::IfcConnectionTypeEnum::IfcConnectionType_ATEND
			? own_axis_end
			: own_axis_start;
		const IfcSchema::IfcProduct* other_wall = it->second;

		gp_Trsf other;
		if (!convert(other_wall->ObjectPlacement(), other)) {
			continue;
		}

		IfcSchema::IfcRepresentation* axis_representation = find_representation(other_wall, "Axis");
		
		IfcRepresentationShapeItems axis_items;
		{
			Kernel temp = *this;
			temp.setValue(GV_DIMENSIONALITY, -1.);
			temp.convert_shapes(axis_representation, axis_items);
		}

		TopoDS_Shape axis_shape;
		flatten_shape_list(axis_items, axis_shape, false);
		
		// local and other are IfcLocalPlacements and therefore have a unit
		// scale factor that can be applied by means of TopoDS_Shape::Move()
		axis_shape.Move(other);
		axis_shape.Move(local);
		
		TopoDS_Shape body_shape;
		flatten_shape_list(items, body_shape, false);

		Handle_Geom_Curve axis_curve;
		double axis_u1, axis_u2;
				
		{ 
			TopExp_Explorer exp(axis_shape, TopAbs_EDGE);
			if (!exp.More()) {
				return false;
			}

			TopoDS_Edge axis_edge = TopoDS::Edge(exp.Current());
			axis_curve = BRep_Tool::Curve(axis_edge, axis_u1, axis_u2);

			gp_Pnt other_a_1, other_a_2;
			axis_curve->D0(axis_u1, other_a_1);
			axis_curve->D0(axis_u2, other_a_2);

			if (axis_u2 < axis_u1) {
				std::swap(axis_u1, axis_u2);
			}
			exp.Next();

			for (; exp.More(); exp.Next()) {
				TopoDS_Edge axis_edge2 = TopoDS::Edge(exp.Current());
				TopExp_Explorer exp2(axis_edge2, TopAbs_VERTEX);
				for (; exp2.More(); exp2.Next()) {
					gp_Pnt p = BRep_Tool::Pnt(TopoDS::Vertex(exp2.Current()));
					gp_Pnt pp;
					double u, d;
					if (project(axis_curve, p, pp, u, d)) {
						if (u < axis_u1) axis_u1 = u;
						if (u > axis_u2) axis_u2 = u;
					}
				}				
			}
		}
		
		double layer_offset = 0;
		
		std::vector<double>::const_iterator thickness = thicknesses.begin();
		result_t::iterator result_vector = result.begin() + 1;

		for (surfaces_t::const_iterator jt = surfaces.begin() + 1; jt != surfaces.end() - 1; ++jt, ++result_vector) {
			layer_offset += *thickness++;

			bool found_intersection = false;
			boost::optional<gp_Pnt> point_outside_param_range;
			//double param;
				
			const Handle_Geom_Surface& surface = *jt;

			GeomAPI_IntCS intersections(axis_curve, surface);
			if (intersections.IsDone() && intersections.NbPoints() == 1) {
				const gp_Pnt& p = intersections.Point(1);
				double u, v, w;
				intersections.Parameters(1, u, v, w);
				if (w < axis_u1 || w > axis_u2) {
					point_outside_param_range = p;
					//param = w;
				} else {
					// Found an intersection. Layer end point is covered by connecting wall
					found_intersection = true;
					break;
				}
			}

			if (!found_intersection && point_outside_param_range) {

				/*
				Is there a bug in Open Cascade related to the intersection
				of offset surfaces constructed from linear extrusions?
				Handle_Geom_Surface xy = new Geom_Plane(gp::Origin(), gp::DZ());
				// Handle_Geom_Surface yz = new Geom_Plane(gp::Origin(), gp::DX());
				// Handle_Geom_Surface yz2 = new Geom_OffsetSurface(yz, 1.);
				Handle_Geom_Curve ln = new Geom_Line(gp::Origin(), gp::DX());
				Handle_Geom_Surface yz = new Geom_SurfaceOfLinearExtrusion(ln, gp::DZ());
				Handle_Geom_Surface yz2 = new Geom_OffsetSurface(yz, 1.);
				intersect(xy, yz2);
				*/
				
				Handle_Geom_Surface plane = new Geom_Plane(*point_outside_param_range, gp::DZ());

				curves_on_surfaces_t layer_ends;
				intersect(surface, body_shape, layer_ends);

				Handle_Geom_Curve layer_body_intersection;
				Handle_Geom_Surface body_surface;
				double mind = std::numeric_limits<double>::infinity();
				for (curves_on_surfaces_t::const_iterator kt = layer_ends.begin(); kt != layer_ends.end(); ++kt) {
					gp_Pnt p;
					gp_Vec v;
					double u, d;
					kt->second->D1(0., p, v);
					if (ALMOST_THE_SAME(0., v.Dot(gp::DZ()))) {
						// Filter horizontal curves
						continue;
					}
					if (project(kt->second, own_end_point, p, u, d)) {
						if (d < mind) {
							body_surface = kt->first;
							layer_body_intersection = kt->second;
							mind = d;
						}
					}
				}

				GeomAPI_IntCS intersection2(layer_body_intersection, plane);
				if (intersection2.IsDone() && intersection2.NbPoints() == 1) {
					const gp_Pnt& layer_end_point = intersection2.Point(1);
					GeomAPI_IntSS intersection3(surface, plane, 1.e-7);
					if (intersection3.IsDone() && intersection3.NbLines() == 1) {
						Handle_Geom_Curve layer_line = intersection3.Line(1);
						GeomAdaptor_Curve layer_line_adaptor(layer_line);
						ShapeAnalysis_Curve sac;
						gp_Pnt layer_end_point_projected; double layer_end_point_param;
						sac.Project(layer_line, layer_end_point, 1e-3, layer_end_point_projected, layer_end_point_param, false);

						GCPnts_AbscissaPoint dst(layer_line_adaptor, layer_offset, layer_end_point_param);
						if (dst.IsDone()) {
							gp_Pnt layer_fold_point;
							layer_line->D0(dst.Parameter(), layer_fold_point);
							
							GeomAPI_IntSS intersection4(body_surface, plane, 1.e-7);
							if (intersection4.IsDone() && intersection4.NbLines() == 1) {
								Handle_Geom_Curve body_trim_curve = intersection4.Line(1);
								ShapeAnalysis_Curve sac2;
								gp_Pnt layer_fold_point_projected; double layer_fold_point_param;
								sac2.Project(body_trim_curve, layer_fold_point, 1.e-7, layer_fold_point_projected, layer_fold_point_param, false);
								Handle_Geom_Curve fold_curve = new Geom_OffsetCurve(body_trim_curve->Reversed(), layer_fold_point_projected.Distance(layer_fold_point), gp::DZ());

								Handle_Geom_Surface fold_surface = new Geom_SurfaceOfLinearExtrusion(fold_curve, gp::DZ());
								result_vector->push_back(fold_surface);
								folds_made = true;
							}
						}
					}
				}
					
			}
		
		}
	}

	return folds_made;
}

bool IfcGeom::Kernel::apply_folded_layerset(const IfcRepresentationShapeItems& items, const std::vector< std::vector<Handle_Geom_Surface> >& surfaces, const std::vector<const SurfaceStyle*>& styles, IfcRepresentationShapeItems& result) {
	Bnd_Box bb;
	TopoDS_Shape input;
	flatten_shape_list(items, input, false);
	BRepBndLib::Add(input, bb);
	std::vector<double> bb_coords(6);
	bb.Get(bb_coords[0], bb_coords[1], bb_coords[2], bb_coords[3], bb_coords[4], bb_coords[5]);

	typedef std::vector< std::vector<Handle_Geom_Surface> > folded_surfaces_t;
	typedef std::vector< std::pair< TopoDS_Face, std::pair<gp_Pnt, gp_Pnt> > > faces_with_mass_t;

	std::vector<TopoDS_Shell> shells;

	// result = items;
	for (folded_surfaces_t::const_iterator it = surfaces.begin(); it != surfaces.end(); ++it) {
		if (it->empty()) {
			continue;
		} else if (it->size() == 1) {
			const Handle_Geom_Surface& surface = (*it)[0];
			double u1, v1, u2, v2;
			if (!project(surface, input, u1, v1, u2, v2)) {
				continue;
			}
			shells.push_back(BRepBuilderAPI_MakeShell(surface, u1, v1, u2, v2).Shell());
		} else {
			faces_with_mass_t solids;		
			for (folded_surfaces_t::value_type::const_iterator jt = it->begin(); jt != it->end(); ++jt) {
				const Handle_Geom_Surface& surface = *jt;
				double u1, v1, u2, v2;
				if (!project(surface, input, u1, v1, u2, v2)) {
					continue;
				}
				TopoDS_Face face = BRepBuilderAPI_MakeFace(surface, u1, u2, v1, v2, 1.e-7).Face();
				gp_Pnt p, p1, p2; gp_Vec vu, vv, n;
				surface->D1((u1+u2)/2., (v1+v2)/2., p, vu, vv);
				n = vu ^ vv;
				p1 = p.Translated( n);
				p2 = p.Translated(-n);
				solids.push_back(std::make_pair(face, std::make_pair(p1, p2)));
			}
			

			if (solids.empty()) {
				continue;
			}

			faces_with_mass_t::iterator jt = solids.begin();
			TopoDS_Face& A = jt->first;
			TopoDS_Shape An = BRepPrimAPI_MakeHalfSpace(A, jt->second.second).Solid();
			for (++jt; jt != solids.end(); ++jt) {
				TopoDS_Face& B = jt->first;
				TopoDS_Shape Bn = BRepPrimAPI_MakeHalfSpace(B, jt->second.second).Solid();

				TopoDS_Shape a = BRepAlgoAPI_Cut(A, Bn);
				if (count(a, TopAbs_FACE) == 1) {
					A = TopoDS::Face(TopExp_Explorer(a, TopAbs_FACE).Current());
				}

				TopoDS_Shape b = BRepAlgoAPI_Cut(B, An);
				if (count(b, TopAbs_FACE) == 1) {
					B = TopoDS::Face(TopExp_Explorer(b, TopAbs_FACE).Current());
				}
			}

			BRepOffsetAPI_Sewing builder;
			for (faces_with_mass_t::const_iterator kt = solids.begin(); kt != solids.end(); ++kt) {
				builder.Add(kt->first);
			}
		
			builder.Perform();
			shells.push_back(TopoDS::Shell(builder.SewedShape()));
		}
	}

	if (shells.empty()) {

		return false;

	} else if (shells.size() == 1) {
		
		for (IfcRepresentationShapeItems::const_iterator it = items.begin(); it != items.end(); ++it) {
			TopoDS_Shape a,b;
			if (split_solid_by_shell(it->Shape(), shells[0], a, b)) {
				result.push_back(IfcRepresentationShapeItem(it->Placement(), b, styles[0] ? styles[0] : &it->Style()));
				result.push_back(IfcRepresentationShapeItem(it->Placement(), a, styles[1] ? styles[1] : &it->Style()));
			} else {
				continue;
			}
		}

		return true;

	} else {

		typedef std::vector< std::vector<TopoDS_Shape> > temp_t;
		temp_t temp;

		for (IfcRepresentationShapeItems::const_iterator it = items.begin(); it != items.end(); ++it) {
			const TopoDS_Shape& s = it->Shape();
			TopoDS_Solid sld;
			ensure_fit_for_subtraction(s, sld);
			std::vector<TopoDS_Shape> temp2;
			temp2.push_back(sld);
			temp.push_back(temp2);
		}

		for (unsigned i = 0; i < shells.size(); ++i) {
			for(temp_t::iterator it = temp.begin(); it != temp.end(); ++it) {
				TopoDS_Shape a,b;
				TopoDS_Shape& ab = (*it)[(*it).size() - 1];
				
				if (split_solid_by_shell(ab, shells[i], a, b)) {
					ab = b;
					it->push_back(a);
				} else {
					continue;
				}
			}
		}

		IfcRepresentationShapeItems::const_iterator it1 = items.begin();
		temp_t::const_iterator it2 = temp.begin();
		
		for(; it1 != items.end(); ++it1, ++it2) {
			std::vector<const SurfaceStyle*>::const_iterator it4 = styles.begin();
			for (temp_t::value_type::const_iterator it3 = it2->begin(); it3 != it2->end(); ++it3, ++it4) {
				result.push_back(IfcRepresentationShapeItem(it1->Placement(), *it3, (*it4) ? (*it4) : &it1->Style()));
			}
		}

		return true;

	}

}

bool IfcGeom::Kernel::apply_layerset(const IfcRepresentationShapeItems& items, const std::vector<Handle_Geom_Surface>& surfaces, const std::vector<const SurfaceStyle*>& styles, IfcRepresentationShapeItems& result) {
	if (surfaces.size() < 3) {

		return false;

	} else if (surfaces.size() == 3) {
		
		for (IfcRepresentationShapeItems::const_iterator it = items.begin(); it != items.end(); ++it) {
			TopoDS_Shape a,b;
			if (split_solid_by_surface(it->Shape(), surfaces[1], a, b)) {
				result.push_back(IfcRepresentationShapeItem(it->Placement(), b, styles[0] ? styles[0] : &it->Style()));
				result.push_back(IfcRepresentationShapeItem(it->Placement(), a, styles[1] ? styles[1] : &it->Style()));
			} else {
				continue;
			}
		}

		return true;

	} else {

		/*
		// Determine whether sequence of surfaces is consistent with surface normal, so that
		// layer operations are applied in the correct order. This seems to be always the case.
		Bnd_Box bb;
		for (IfcRepresentationShapeItems::const_iterator it = items.begin(); it != items.end(); ++it) {
			BRepBndLib::Add(it->Shape(), bb);
		}

		double x1, y1, z1, x2, y2, z2; 
		bb.Get(x1, y1, z1, x2, y2, z2);
		gp_Pnt p1(x1, y1, z1);
		gp_Pnt p2(x2, y2, z2);
		gp_Pnt avg = (p1.XYZ() + p2.XYZ()) / 2.;

		ShapeAnalysis_Surface sas1(surfaces[0]);
		ShapeAnalysis_Surface sas2(surfaces[1]);
		const gp_Pnt2d uv = sas1.ValueOfUV(avg, 1e-3);
		
		gp_Pnt ps1, ps2, mass;
		gp_Vec du1, dv1, du2, dv2;
		surfaces[0]->D1(uv.X(), uv.Y(), ps1, du1, dv1);
		const gp_Vec n1 = dv1.XYZ() ^ du1.XYZ();
		
		const bool reversed = gp_Dir(ps2.XYZ() - ps1.XYZ()).Dot(n1) < 0.;
		
		surfaces[surfaces.size() - 1]->D0(uv.X(), uv.Y(), mass);
		mass.ChangeCoord() += n1.XYZ();
		*/
		
		typedef std::vector< std::vector<TopoDS_Shape> > temp_t;
		temp_t temp;

		for (IfcRepresentationShapeItems::const_iterator it = items.begin(); it != items.end(); ++it) {
			// No transformation on purpose in order not interfere with layerset alignment
			const TopoDS_Shape& s = it->Shape();
			TopoDS_Solid sld;
			ensure_fit_for_subtraction(s, sld);
			std::vector<TopoDS_Shape> temp2;
			temp2.push_back(sld);
			temp.push_back(temp2);
		}

		for (unsigned i = 1; i < surfaces.size() - 1; ++i) {
			for(temp_t::iterator it = temp.begin(); it != temp.end(); ++it) {
				TopoDS_Shape a,b;
				TopoDS_Shape& ab = (*it)[(*it).size() - 1];
				
				if (split_solid_by_surface(ab, surfaces[i], a, b)) {
					ab = b;
					it->push_back(a);
				} else {
					continue;
				}
			}
		}

		IfcRepresentationShapeItems::const_iterator it1 = items.begin();
		temp_t::const_iterator it2 = temp.begin();
		
		for(; it1 != items.end(); ++it1, ++it2) {
			std::vector<const SurfaceStyle*>::const_iterator it4 = styles.begin();
			for (temp_t::value_type::const_iterator it3 = it2->begin(); it3 != it2->end(); ++it3, ++it4) {
				result.push_back(IfcRepresentationShapeItem(it1->Placement(), *it3, (*it4) ? (*it4) : &it1->Style()));
			}
		}

		return true;
	}
}

IfcSchema::IfcRepresentation* IfcGeom::Kernel::find_representation(const IfcSchema::IfcProduct* product, const std::string& identifier) {
	if (!product->hasRepresentation()) return 0;
	IfcSchema::IfcProductRepresentation* prod_rep = product->Representation();
	IfcSchema::IfcRepresentation::list::ptr reps = prod_rep->Representations();
	for (IfcSchema::IfcRepresentation::list::it it = reps->begin(); it != reps->end(); ++it) {
		if ((**it).hasRepresentationIdentifier() && (**it).RepresentationIdentifier() == identifier) {
			return *it;
		}
	}
	return 0;
}

bool IfcGeom::Kernel::split_solid_by_surface(const TopoDS_Shape& input, const Handle_Geom_Surface& surface, TopoDS_Shape& front, TopoDS_Shape& back) {
	// Use an unbounded surface, that isolate part of the input shape,
	// to split this shape into two parts. Make sure that the addition
	// of the two result volumes matches that of the input.

	double u1, v1, u2, v2;
	if (!project(surface, input, u1, v1, u2, v2)) {
		return false;
	}

	TopoDS_Face face = BRepBuilderAPI_MakeFace(surface, u1, u2, v1, v2, 1.e-7).Face();
	gp_Pnt p, p1, p2; gp_Vec vu, vv, n;
	surface->D1((u1+u2)/2., (v1+v2)/2., p, vu, vv);
	n = vu ^ vv;
	p1 = p.Translated(-n);
	TopoDS_Solid solid = BRepPrimAPI_MakeHalfSpace(face, p1).Solid();

	const bool b = split_solid_by_shell(input, solid, front, back);
	return b;
}

bool IfcGeom::Kernel::split_solid_by_shell(const TopoDS_Shape& input, const TopoDS_Shape& shell, TopoDS_Shape& front, TopoDS_Shape& back) {
	// Use a shell, typically one or more connected faces, that isolate part
	// of the input shape, to split this shape into two parts. Make sure that
	// the addition of the two result volumes matches that of the input.
	
	TopoDS_Solid solid;
	if (shell.ShapeType() == TopAbs_SHELL) {
		solid = BRepBuilderAPI_MakeSolid(TopoDS::Shell(shell)).Solid();
	} else if (shell.ShapeType() == TopAbs_SOLID) {
		solid = TopoDS::Solid(shell);
	} else {
		return false;
	}
	apply_tolerance(solid, getValue(GV_PRECISION));

	BOPCol_ListOfShape shapes;
	shapes.Append(input);
	shapes.Append(solid);
	BOPAlgo_PaveFiller filler(new NCollection_IncAllocator); // TODO: Does this need to be freed?
	filler.SetArguments(shapes);
	filler.Perform();
	front = BRepAlgoAPI_Cut(input, solid, filler);
	back = BRepAlgoAPI_Common(input, solid, filler);

	bool is_null[2];

	for (int i = 0; i < 2; ++i) {
		TopoDS_Shape& shape = i == 0 ? front : back;
        const bool result_is_null = is_null[i] = shape.IsNull() != 0;
		if (result_is_null) {
			continue;
		}
		try {
			ShapeFix_Shape fix(shape);
			if (fix.Perform()) {
				shape = fix.Shape();
			}
		} catch(...) {}
		BRepCheck_Analyzer analyser(shape);
		bool is_valid = analyser.IsValid() != 0;
		if (!is_valid) {
			return false;
		}
	}

	if (is_null[0] || is_null[1]) {
		Logger::Message(Logger::LOG_ERROR, "Null result obtained from layerset slicing");
		if (is_null[0] && is_null[1]) {
			return false;
		}
	}

	const double ab = shape_volume(input);
	const double a  = shape_volume(front);
	const double b  = shape_volume(back);

	return ALMOST_THE_SAME(ab, a+b, 1.e-3);
}

bool IfcGeom::Kernel::project(const Handle_Geom_Surface& srf, const TopoDS_Shape& shp, double& u1, double& v1, double& u2, double& v2, double widen) {
	ShapeAnalysis_Surface sas(srf);

	u1 = v1 = +std::numeric_limits<double>::infinity();
	u2 = v2 = -std::numeric_limits<double>::infinity();

	gp_Pnt median;
	int vertex_count = 0;
	for (TopExp_Explorer exp(shp, TopAbs_VERTEX); exp.More(); exp.Next(), ++vertex_count) {
		gp_Pnt p = BRep_Tool::Pnt(TopoDS::Vertex(exp.Current()));
		median.ChangeCoord() += p.XYZ();

		const gp_Pnt2d uv = sas.ValueOfUV(p, 1e-3);
		
		if (uv.X() < u1) u1 = uv.X();
		if (uv.Y() < v1) v1 = uv.Y();
		if (uv.X() > u2) u2 = uv.X();
		if (uv.Y() > v2) v2 = uv.Y();
	}

	if (vertex_count == 0) {
		return false;
	}

	// Add a little bit of resulution so that the median is shifted towards the mass
	// of the curve. This helps to find the parameter ordering for conic surfaces.
	for (TopExp_Explorer exp(shp, TopAbs_EDGE); exp.More(); exp.Next(), ++vertex_count) {
		const TopoDS_Edge& e = TopoDS::Edge(exp.Current());
		
		double a, b;
		Handle_Geom_Curve crv = BRep_Tool::Curve(e, a, b);
		gp_Pnt p;
		crv->D0((a + b) / 2., p);

		median.ChangeCoord() += p.XYZ();
	}
	
	median.ChangeCoord().Divide(vertex_count);
	const gp_Pnt2d uv = sas.ValueOfUV(median, 1e-3);
	
	if (uv.X() < u1 || uv.X() > u2) {
		std::swap(u1, u2);
	}

	u1 -= widen;
	u2 += widen;
	v1 -= widen;
	v2 += widen;
	
	return true;
}

const IfcSchema::IfcRepresentationItem* IfcGeom::Kernel::find_item_carrying_style(const IfcSchema::IfcRepresentationItem* item) {
	if (item->StyledByItem()->size()) {
		return item;
	}

	while (item->is(IfcSchema::Type::IfcBooleanClippingResult)) {
		// All instantiations of IfcBooleanOperand (type of FirstOperand) are subtypes of
		// IfcGeometricRepresentationItem
		item = (IfcSchema::IfcGeometricRepresentationItem*) ((IfcSchema::IfcBooleanClippingResult*) item)->FirstOperand();
		if (item->StyledByItem()->size()) {
			return item;
		}
	}

	// TODO: Ideally this would be done for other entities (such as IfcCsgSolid) as well.
	// But neither are these very prevalent, nor does the current IfcOpenShell style
	// mechanism enable to conveniently style subshapes, which would be necessary for
	// distinctly styled union operands.

	return item;
}

bool IfcGeom::Kernel::is_identity_transform(IfcUtil::IfcBaseClass* l) {
	IfcSchema::IfcAxis2Placement2D* ax2d;
	IfcSchema::IfcAxis2Placement3D* ax3d;

	IfcSchema::IfcCartesianTransformationOperator2D* op2d;
	IfcSchema::IfcCartesianTransformationOperator3D* op3d;
	IfcSchema::IfcCartesianTransformationOperator2DnonUniform* op2dnonu;
	IfcSchema::IfcCartesianTransformationOperator3DnonUniform* op3dnonu;

	if((op2dnonu = l->as<IfcSchema::IfcCartesianTransformationOperator2DnonUniform>()) != 0) {
		gp_GTrsf2d gtrsf2d;
		convert(op2dnonu, gtrsf2d);
		return gtrsf2d.Form() == gp_Identity;
	} else if ((op2d = l->as<IfcSchema::IfcCartesianTransformationOperator2D>()) != 0) {
		gp_Trsf2d trsf2d;
		convert(op2d, trsf2d);
		return trsf2d.Form() == gp_Identity;
	} else if((op3dnonu = l->as<IfcSchema::IfcCartesianTransformationOperator3DnonUniform>()) != 0) {
		gp_GTrsf gtrsf;
		convert(op3dnonu, gtrsf);
		return gtrsf.Form() == gp_Identity;
	} else if ((op3d = l->as<IfcSchema::IfcCartesianTransformationOperator3D>()) != 0) {
		gp_Trsf trsf;
		convert(op3d, trsf);
		return trsf.Form() == gp_Identity;
	} else if((ax2d = l->as<IfcSchema::IfcAxis2Placement2D>()) != 0) {
		gp_Trsf2d trsf2d;
		convert(ax2d, trsf2d);
		return trsf2d.Form() == gp_Identity;
	} else if ((ax3d = l->as<IfcSchema::IfcAxis2Placement3D>()) != 0) {
		gp_Trsf trsf;
		convert(ax3d, trsf);
		return trsf.Form() == gp_Identity;
	} else {
		throw IfcParse::IfcException("Invalid valuation for IfcAxis2Placement / IfcCartesianTransformationOperator");
	}
}

bool IfcGeom::Kernel::approximate_plane_through_wire(const TopoDS_Wire& wire, gp_Pln& plane) {
	// Newell's Method is used for the normal calculation
	// as a simple edge cross product can give opposite results
	// for a concave face boundary.
	// Reference: Graphics Gems III p. 231

	double x = 0, y = 0, z = 0;
	gp_Pnt current, previous, first;
	gp_XYZ center;
	int n = 0;
	
	BRepTools_WireExplorer exp(wire);

	for (;; exp.Next()) {
		const bool has_more = exp.More() != 0;
		if (has_more) {
			const TopoDS_Vertex& v = exp.CurrentVertex();
			current = BRep_Tool::Pnt(v);
			center += current.XYZ();
		} else {
			current = first;
		}
		if (n) {
			const double& xn = previous.X();
			const double& yn = previous.Y();
			const double& zn = previous.Z();
			const double& xn1 = current.X();
			const double& yn1 = current.Y();
			const double& zn1 = current.Z();
			x += (yn - yn1)*(zn + zn1);
			y += (xn + xn1)*(zn - zn1);
			z += (xn - xn1)*(yn + yn1);
		} else {
			first = current;
		}
		if (!has_more) {
			break;
		}
		previous = current;
		++n;
	}

	if (n < 3) {
		return false;
	}

	plane = gp_Pln(center / n, gp_Dir(x, y, z));
	return true;
}

bool IfcGeom::Kernel::flatten_wire(TopoDS_Wire& wire) {
	gp_Pln pln;
	if (!approximate_plane_through_wire(wire, pln)) {
		return false;
	}
	TopoDS_Face face = BRepBuilderAPI_MakeFace(pln).Face();
	BRepAlgo_NormalProjection proj(face);
	proj.Add(wire);
	proj.Build();
	if (!proj.IsDone()) {
		return false;
	}
	TopTools_ListOfShape list;
	proj.BuildWire(list);
	if (list.Extent() != 1) {
		return false;
	}
	wire = TopoDS::Wire(list.First());
	return true;
}


TopoDS_Shape IfcGeom::Kernel::apply_transformation(const TopoDS_Shape& s, const gp_Trsf& t) {
	if (t.Form() == gp_Identity) {
		return s;
	} else {
		/// @todo set to 1. and exactly 1. or use epsilon?
		if (t.ScaleFactor() != 1.) {
			return BRepBuilderAPI_Transform(s, t, true);
		} else {
			return s.Moved(t);
		}
	}
}

TopoDS_Shape IfcGeom::Kernel::apply_transformation(const TopoDS_Shape& s, const gp_GTrsf& t) {
	if (t.Form() == gp_Other) {
		return BRepBuilderAPI_GTransform(s, t, true);
	} else {

		return apply_transformation(s, t.Trsf());
	}
}

